Q. What is your research specialty?

I research nonthermal phenomena. All natural phenomena on Earth have a temperature, but in various parts of the universe there is matter that we cannot measure a temperature for at all. Temperature is a measure of the microscopic motion – also known as kinetic energy – of molecules and atoms in matter, and the quantity of kinetic energy dictates the thermal energy. We measure this as temperature.
But there are some phenomena observed in space that do not conform to our Earth-bound physical laws related to heat and temperature. These phenomena are referred to as nonthermal phenomena, and cannot be defined by their temperature in degrees Celsius.
For example, nonthermal particles were found in shockwaves from a supernova explosion and a high-speed jet released from a location very close to a black hole. These nonthermal particles accelerate to a very high energy that is not realistic on the ground. We do not yet understand how these nonthermal particles are created and how they accelerate.
It is the extreme and uneven velocities of these particles in space that make it impossible for us to measure their temperature and define them as nonthermal particles.

Q. What kind of research would you like to do with the X-ray Astronomy Satellite ASTRO-H?

ASTRO-H’s main feature is its wideband observation ability. It has at least ten times more energy resolution than traditional X-ray astronomy satellites. I’d like to make precise observations on the kinetic state of collisionless plasmas seen in shockwaves from a supernova explosion, in order to learn what kind of plasmas are accelerated to high-energy states.

Q. Why are you interested in supernova explosions?

X-ray image of the supernova remnant Cassiopeia A, 330 years after its supernova explosion. X-rays are shown from high-energy to low-energy as blue, green and red. (courtesy: NASA/CXC/UMass Amherst/M.D.Stage et al.)
X-ray image of Tycho’s supernova remnant. The purple area seen on the outer rim is a shockwave where high-energy non-thermal particles are accelerated. (courtesy: NASA/CXC/Rutgers/J. Warren & J. Hughes et al.)

I have always had an interest in the fact that the particles created from a supernova explosion are accelerated to a very high energy. I’m attracted by high-energy phenomena.
Everything on Earth has a temperature that we can measure and define, but in supernova remnants, we cannot measure the temperature of the high-energy particles, which are called “nonthermal” particles.
Such phenomena, which are never seen on Earth, make supernova explosions and their remnants very interesting. These nonthermal phenomena are observed universally all over space, and there is a possibility of something very important being hidden there. I find this mystery very compelling.
When you look at the photos of supernova remnants, they are very beautiful. That’s another reason why I am so interested in supernova explosions.

Q. What are supernova explosions and supernova remnants?

A supernova explosion is a phenomenon in which a star reaches the end of its life and explodes. For example, think about a “heavy” star, which means it has more than ten times the mass of the Sun. First, a star is created when clouds of gas in space are attracted and contracted by gravity. In the center of a star, nuclear fusion (in which hydrogen gas becomes helium, and so on to larger and larger atoms) will occur and generate outward pressure. Since that pressure and the gravity of the star are well balanced, the star can maintain its shape. The energy of the atomic fusion reaction creates the light that makes the star shine.
Nuclear fusion will continue until iron forms in the core of a star. Iron is a stable atomic nucleus, so no further nuclear fusion will occur. About a million years after its birth, the star reaches a destruction period known as “iron photodisintegration.” The pressure of the “core” decreases rapidly and the star, when it can no longer tolerate the gravity, shatters and explodes. This is a supernova explosion of a heavy star.
During the supernova explosion, enormous energy is released, and the shockwaves spread into the universe. One explosion of a supernova shines as brightly as a collection of 100 billion stars. Shockwaves also emit X-rays or gamma rays (which have an energy even greater than X-rays). Such shockwaves generated from a big star explosion are known as supernova remnants. A supernova explosion itself lasts only a few seconds, but a supernova remnant will exist in space for more than 100,000 years.

Q. What can we learn by studying supernova explosions and remnants?

The supernova remnant G292.0+1.8. When its nuclear fusion reaches its limit, a star dies in a big explosion, as gravity destroys its nucleus. Heavy elements released into space at that time become the origin of life. In this remnant, we can see a lot of oxygen. (courtesy: X-ray: NASA/CXC/Penn State/S.Park et al.; Optical: Pal.Obs. DSS)

We can learn how the universe evolved, how it reached its present state, and where living things came from. As a matter of fact, the elements that make up our body came from supernova explosions. If there were no supernova explosions, no living things would have formed.
Most elements around us that are lighter than iron – such as oxygen and nitrogen – are created through nuclear fusion in stars. These elements were spread throughout the universe by supernova explosions. They are then thought to have gathered to create our Earth and all living organisms on it.
Furthermore, we have learned that many elements heavier than iron – through to the heaviest element in nature, uranium – were created at the moment of a supernova explosion and scattered through the universe. This is even true of gold and silver, on which humanity places a special value. By studying supernova remnants, we can understand where and how these elements around us were created.
Supernova explosions generate cosmic rays. Cosmic rays are high-energy particles flying about the universe at high speed. X-rays and high-energy gamma rays are released from supernova remnants as an indication of the existence of cosmic rays. That is to say, a leading theory is that nonthermal particles in shockwaves are cosmic rays.
Cosmic rays also do come down to Earth’s surface, but even 100 years after their discovery, their origin remains unknown. Some people believe that cosmic rays play a very important role in the formation of stars. Lithium used in batteries is created from a crash between cosmic rays and interstellar gas in space. In such a way, everything is linked. So when we learn more about supernova remnants, we will be better equipped to explore and perhaps even solve the mysteries of the universe, and perhaps even of lifeforms unknown to us today. This is very interesting.